JP3099305U - Motor lock cooling circuit - Google Patents

Abstract

A method for detecting a signal for automatic start-up reduces the discharge time of a start-up discharge capacitor, and reduces the time for conduction of the coil in automatic start-up, thereby reducing burning of the motor. Provide a motor lock temperature reduction circuit that can
The driving device includes a driving element, a coil set, a discharge switch set, and a starting discharge capacitor. Each of the driving elements is connected to the coil set and the starting discharge capacitor, and the discharge switch set is connected between the coil set and the starting discharge capacitor, and can block the output of the driving element. When the operation of the motor is abnormally formed, the automatic activation function of the driving element is activated, and when the driving element outputs a high level or a low level, the discharge switch set is formed to open, The discharge of the starting discharge capacitor is configured to be accelerated.
[Selection diagram] Fig. 1

Description

The present invention relates to a temperature reduction circuit of a motor lock, and in particular, by detecting a signal of an automatic start, the coil shortens a conduction time in the automatic start, so that a rotation speed of the motor decreases, a lock or an overcurrent occurs. The present invention relates to a temperature reduction circuit for a motor lock, which can prevent a motor from burning due to overheating at the time of occurrence, and can be applied particularly to a drive element of a discharge type automatic start.

In general fan motors, two types of abnormal conditions tend to occur during use, and one type of abnormal condition tends to accumulate debris over a long period of use. In the abnormal state, the motor cannot rotate because foreign matter enters the blade or the inside of the motor. In such two kinds of abnormal states, the current of the winding coil is formed to rise rapidly. A large amount of power is consumed by the large current of the coil, and the large amount of power is converted into heat, which not only raises the temperature significantly, but also accelerates the deterioration due to the power of the coil. Therefore, the temperature of the winding coil is further increased. As the temperature of the winding coil increases, the insulating layer of the enamel wire also changes in quality and cracks occur, and the cracks in the enamel wire cause the winding coil to be short-circuited and burnt.

(5) In a conventional fan motor, in order to prevent a large current from passing through a winding coil in an abnormal state, a motor drive IC is generally provided with an automatic starting function in order to prevent a large current from passing therethrough. When the motor drive IC is in an abnormal state, the fan motor is automatically started once at every scheduled time interval. If the fan motor cannot be started, there is a method in which the electricity is first turned off, the scheduled time is again set, and then the fan motor is automatically started again.

Further, in the circuit diagram of the conventional two-phase DC brushless fan motor drive circuit shown in FIG. 5, the motor drive circuit 1 includes a drive element 10, two coils 11, two transistors 12, and a starting discharge capacitor 13. It is. Scheduled ON and OFF times are provided in the automatic starting function of the motor drive circuit 1, and the proportion of the ON and OFF times is determined by the charging and discharging times of the starting discharge capacitor 13. Some motor drive circuits 1 output signals according to the ON and OFF times to control the conduction and opening and closing of the transistor 12.

In addition, in the circuit diagram of the conventional single-phase DC brushless fan motor drive circuit shown in FIG. 6, the motor drive circuit 2 includes a drive element 20, a coil 21, and a starting discharge capacitor 22. In some motor drive circuits 2, ON and OFF times are determined by a starting discharge capacitor 22, and a signal is output to control conduction and opening and closing of the coil 21.

In the circuit diagram of the conventional two-phase DC brushless fan motor drive circuit shown in FIG. 7, the motor drive circuit 3 includes a drive element 30, two coils 31, and a starting discharge capacitor 32. In some motor drive circuits 3, ON and OFF times are determined by a starting discharge capacitor 32, and a signal is output to control conduction and opening and closing of the coil 31.

Further, in the waveform diagrams of the driving element and the starting discharge capacitor of the conventional DC brushless fan motor driving circuit shown in FIGS. 8A and 8B, referring to FIG. 8A, when the starting discharge capacitor C is charged while the fan motor is locked. The driving element outputs a low level (Lo) within T1, while the driving element outputs a high level (Hi) within T2 when the starting discharge capacitor C discharges. Referring to FIG. 8B, when the starting discharge capacitor C is charging when the fan motor is locked, the driving element outputs a high level (Hi) within T1, whereas when the starting discharging capacitor C discharges, the driving element outputs a high level (Hi). Is designed to output a low level (Lo) within T2.

In the waveform diagram of the driving element and the starting discharge capacitor of the driving circuit of the conventional DC brushless fan motor as described above, the charging and discharging times of the starting discharge capacitor C are fixed. Fixed. Then, when the start-up discharge capacitors 13, 22, and 32 are charged, the fan motor automatically starts using the maximum consumption current within T1, so that the fan motor has not yet been released from the locked state. Then, the automatic start is maintained based on the time T2. For a low-airflow or low-power fan motor, automatic startup using the maximum consumption current did not cause the problem of large power consumption and high heat generation, but a high-airflow or high-power fan The motor has a problem that when the fan motor is abnormal, the instantaneous current of the coil reaches several amperes or more, so that a large amount of power is consumed and a high temperature is generated, thereby burning the motor.

The present invention has been devised in view of such a problem, and its purpose is to reduce a discharge time of a start discharge capacitor by a method of detecting an automatic start signal, thereby automatically setting a coil. An object of the present invention is to provide a motor lock temperature lowering circuit that can reduce the burning of the motor because the conduction time during startup can be reduced.

The first object of the present invention is to reduce the discharge time of the starting discharge capacitor by the method of detecting the signal of automatic starting, and to shorten the conduction time in the automatic starting of the coil, so that the motor burns. It is an object of the present invention to provide a motor lock temperature lowering circuit that can reduce the occurrence of the temperature drop.

The second object of the present invention is to reduce the discharge time of the start-up discharge capacitor by detecting the signal of the automatic start-up, and apply it to the drive element of the discharge type automatic start-up, so that the degree of freedom of the drive circuit design An object of the present invention is to provide a motor lock temperature lowering circuit that can increase the temperature.

To achieve the above object, a motor lock temperature lowering circuit according to the present invention is as follows. That is,
It is composed of a drive element, a coil, a discharge switch set, and a starting discharge capacitor. Since the driving element has an automatic start function, the automatic start function is automatically started when the operation of the motor is abnormal. The coil is connected to the drive element, so that the drive element controls conduction and opening and closing of the coil. The discharge switch set is connected to the coil and can block the output of the driving element. The starting discharge capacitor discharges when the automatic starting function of the driving element is started. When the automatic activation function of the driving element is activated, the discharge switch set is formed to be opened, so that the discharge of the activation discharge capacitor can be accelerated.

The motor lock cooling circuit according to the present invention further includes a resistor, the resistor is connected in series between the starting discharge capacitor and the discharge switch set, and the resistance value of the resistor is used to determine the discharge acceleration rate of the starting discharge capacitor. It can also be done. Also, when the operation of the motor is formed in an abnormal state, the automatic activation function of the driving element is activated, and when the driving element outputs a high level, the discharge switch set is formed to be opened, so that the activation is performed. The discharge of the discharge capacitor can be accelerated. Also, when the operation of the motor is formed in an abnormal state, the automatic activation function of the driving element is activated, and when the driving element outputs a low level, the discharge switch group is formed to be opened, thereby being activated. The discharge of the discharge capacitor can be accelerated. Also, the coil can be formed of a two-phase coil. Also, the coil can be a single-phase coil. Also, the discharge switch set can be composed of a pair of diodes. Also, the discharge switch set can be composed of a transistor and a pair of capacitors.

According to the temperature reduction circuit of the motor lock of the present invention, the method of detecting the signal of the automatic start can shorten the discharge time of the start discharge capacitor and shorten the conduction time in the automatic start of the coil, There is an advantage that burning of the motor can be reduced.

According to the motor lock temperature lowering circuit of the present invention, by detecting the signal of the automatic start, the discharge time of the start discharge capacitor is reduced, and the drive circuit is designed to be applied to the drive element of the discharge type automatic start. There is an advantage that the degree of freedom can be increased.

An embodiment of the present invention will be described below with reference to the drawings.

FIG. 1 is a circuit diagram of a two-phase DC brushless fan motor according to a first embodiment of the present invention, which is a motor lock temperature lowering circuit. FIG. 2 is a second embodiment of a single-phase DC brushless fan motor according to a second embodiment of the present invention. FIG. 3 is a circuit diagram of a motor lock of a single-phase DC brushless fan motor according to a third embodiment of the present invention, and FIG. 4 is a circuit diagram of a two-phase DC brushless fan motor of a fourth embodiment of the present invention. FIG. 3 is a circuit diagram of the temperature lowering circuit of FIG.

Referring to FIGS. 1, 2, 3, and 4, the fan motor circuits according to the first, second, third, and fourth embodiments of the present invention are installed corresponding to the conventional circuit. In order to make it easy to understand the difference between the two, the same elements are denoted by the same reference numerals. Further, a part of the technical contents of the first, second, third, and fourth embodiments is described in the conventional explanation contents, and thus will not be described again in detail for reference.

Referring again to FIG. 1, the motor driving circuit 1 according to the first embodiment of the present invention includes a driving element 10, two coils 11, two transistors 12, one starting discharge capacitor 13 and a discharge switch set 14. , The discharge switch set 14 includes a transistor 141 and two capacitors 142. The discharge switch set 14 is connected between the coil 11 and the starting discharge capacitor 13 and can cut off the output of the driving element 10. When the motor is in a normal operating state, the driving element 10 can control the coil 11 by a method of turning on and off the transistor 12. When the motor is in an abnormal operating state, the automatic activation function of the driving element 10 is activated, and the discharge switch set 14 is formed to assist the discharge of the activation discharge capacitor 13, so that the discharge time of the activation discharge capacitor 13 is reduced. Can be shortened. In addition, the resistor 15 is connected in series between the starting discharge capacitor 13 and the discharge switch set 14, and the discharge acceleration rate of the starting discharge capacitor 13 can be determined by the resistance value of the resistor 15.

Referring again to FIGS. 1 and 8A, when the automatic activation function of the driving element 10 is activated, a high level (Hi) is output within T2, and at the same time, the activation discharging capacitor 13 starts discharging through the driving element 10. . At this time, the base of the transistor 141 of the discharge switch set 14 is turned on alternately from the high level (Hi) of C1 or C2 of the two capacitors 142, and is discharged (grounded) through the discharge switch set 14, thereby discharging. Time (T2) can be shortened. When the starting discharge capacitor 13 has finished discharging, the driving element 10 outputs a low level (Lo) within T1, the discharging switch set 14 is cut off from the low level (Lo), and the starting discharge capacitor 13 is charged for a charging time. It is formed so as to enter (T1) and charge through the driving element 10.

Referring to FIG. 2, the motor drive circuit 2 according to the second embodiment of the present invention includes a drive element 20, a coil 21, a starting discharge capacitor 22, and a discharge switch set 23. The discharge switch set 23 includes a transistor 231 and two transistors. Condenser 232 is included. The discharge switch set 23 is connected between the coil 21 and the starting discharge capacitor 22, and can cut off the output of the driving element 20. When the motor is operating normally, the drive element 20 can control the conduction of the coil 21. When the motor is in an abnormal operating state, the automatic activation function of the driving element 20 is activated, and the discharge switch set 23 is formed to assist the discharge of the activation discharge capacitor 22, so that the discharge time of the activation discharge capacitor 22 is reduced. Can be shortened. In addition, the resistor 24 is connected in series between the starting discharge capacitor 22 and the discharge switch set 23, and the discharge acceleration rate of the starting discharge capacitor 22 can be determined by the resistance value of the resistor 24.

Referring again to FIGS. 2 and 8A, when the automatic activation function of the driving element 20 is activated, a high level (Hi) is output within T2, and at the same time, the activation discharging capacitor 22 starts discharging through the driving element 20. . At this time, the base of the transistor 231 of the discharge switch set 23 is turned on alternately from the high level (Hi) of C1 or C2 of the two capacitors 232, and is discharged (grounded) through the discharge switch set 23, thereby discharging. Time (T2) can be shortened. When the starting discharge capacitor 22 has finished discharging, the driving element 20 outputs a low level (Lo) within T1, the discharging switch set 23 is cut off from the low level (Lo), and the starting discharge capacitor 22 is charged for a charging time. It is formed so as to enter (T1) and charge through the driving element 20.

Referring to FIG. 3, the motor drive circuit 2 according to the third embodiment of the present invention includes a drive element 20, a coil 21, a starting discharge capacitor 22, and a discharge switch set 23, as in the second embodiment. A pair of diodes D1 and D2 is included. The discharge switch set 23 is connected between the coil 21 and the starting discharge capacitor 22, and can cut off the output of the driving element 20. When the motor is operating normally, the drive element 20 can control the conduction of the coil 21. When the motor is in an abnormal operating state, the automatic activation function of the driving element 20 is activated, and the discharge switch set 23 is formed to assist the discharge of the activation discharge capacitor 22, so that the discharge time of the activation discharge capacitor 22 is reduced. Can be shortened. In addition, the resistor 24 is connected in series between the starting discharge capacitor 22 and the discharge switch set 23, and the discharge acceleration rate of the starting discharge capacitor 22 can be determined by the resistance value of the resistor 24.

Referring again to FIGS. 3 and 8B, when the automatic activation function of the driving element 20 is activated, the activation discharge capacitor 22 starts discharging at the same time as outputting a low level (LO) within T2. At this time, the diodes D1 or D2 of the discharge switch set 23 are turned on alternately, and the starting discharge capacitor 22 releases the current, so that the discharge time (T2) can be shortened. When the starting discharge capacitor 22 has finished discharging, the driving element 20 outputs a high level (Hi) within T1, and the starting discharging capacitor 22 enters the charging time (T1) to charge through the driving element 20. Formed to do.

Referring to FIG. 4, the motor driving circuit 3 according to the fourth embodiment of the present invention includes a driving element 30, two coils 31, a starting discharge capacitor 32, and a discharge switch set 33, and the discharge switch set 33 includes a transistor 331. And two capacitors 332 are included. The discharge switch set 33 is connected between the coil 31 and the starting discharge capacitor 32 and can cut off the output of the driving element 30. When the motor is in a normal operating state, the driving element 30 can control the coil 31 to be turned on alternately. When the motor is in an abnormal operating state, the automatic activation function of the driving element 30 is activated, and the discharge switch set 33 is formed to assist the discharge of the activation discharge capacitor 32, so that the discharge time of the activation discharge capacitor 32 is reduced. Can be shortened. In addition, the resistor 34 is connected in series between the starting discharge capacitor 32 and the discharge switch set 33, and the discharge acceleration rate of the starting discharge capacitor 32 can be determined by the resistance value of the resistor 34.

Referring again to FIGS. 4 and 8B, when the automatic activation function of the driving element 30 is activated, the activation discharge capacitor 32 starts discharging at the same time as outputting a low level (Lo) within T2. At this time, the base of the transistor 331 of the discharge switch set 33 conducts from the low level (Lo) to activate C1 or C2 of the two capacitors 332, and a current is introduced from the coil 31 to discharge time (T2). Can be shortened. When the starting discharge capacitor 32 has finished discharging, the driving element 30 outputs a high level (Hi) within T1, and the starting discharging capacitor 32 enters the discharging time (T1) and charges through the driving element 30. Formed to do.

According to the temperature reduction circuit of the motor lock of the present invention, the method of detecting the signal of the automatic start can shorten the discharge time of the start discharge capacitor and shorten the conduction time in the automatic start of the coil, The motor can be prevented from burning. Further, since the present invention can be applied to a discharge-type automatic start driving element, the degree of freedom in designing a driving circuit can be increased.

The invention may be implemented in other ways without departing from its spirit and essential characteristics. Accordingly, the preferred embodiments described herein are illustrative and not limiting.

FIG. 3 is a circuit diagram of the motor lock of the two-phase DC brushless fan motor according to the first embodiment of the present invention, which is based on a temperature lowering circuit. FIG. 4 is a circuit diagram of a motor lock of a two-phase DC brushless fan motor according to a second embodiment of the present invention using a temperature-lowering circuit. FIG. 4 is a circuit diagram of a motor lock of a two-phase DC brushless fan motor according to a third embodiment of the present invention using a temperature-lowering circuit; FIG. 4 is a circuit diagram of a motor lock of a two-phase DC brushless fan motor according to a fourth embodiment of the present invention using a cooling circuit. FIG. 4 is a circuit diagram of a conventional two-phase DC brushless fan motor driving circuit. FIG. 9 is a circuit diagram of a conventional single-phase DC brushless fan motor driving circuit. FIG. 4 is a circuit diagram of a conventional two-phase DC brushless fan motor driving circuit. FIG. 9 is a diagram showing waveforms of a driving element and a capacitor of a driving circuit of a conventional DC brushless fan motor. FIG. 9 is a diagram showing waveforms of a driving element and a capacitor of a driving circuit of a conventional DC brushless fan motor.

Explanation of reference numerals

DESCRIPTION OF SYMBOLS 1 Motor drive circuit 10 Driving element 11 Coil 12 Transistor 13 Start discharge capacitor 14 Discharge switch set 141 Transistor 142 Capacitor 15 Resistance 2 Motor drive circuit 20 Drive element 21 Coil 22 Start discharge capacitor 23 Discharge switch set 231 Transistor 232 Capacitor 24 Resistance 3 Motor Drive circuit 30 Drive element 31 Coil 32 Starting discharge capacitor 33 Discharge switch set 331 Transistor 332 Capacitor 34 Resistance C1 Capacitor C2 Capacitor D1 Diode D2 Diode

Claims (8)

This is a motor lock temperature reduction circuit composed of a driving element (10), a coil (11), a discharge switch set (14), and a starting discharge capacitor (13), since the driving element (10) has an automatic starting function. When the operation of the motor is abnormal, the automatic activation function is automatically activated, and the coil (11) is connected to the driving element (10) so that the coil (11) is driven by the driving element (10). ), The discharge switch set (14) is connected to the coil (11), can block the output of the driving element (10), and the starting discharge capacitor (13) is driven. Discharge is performed when the automatic activation function of the element (10) is activated, and the discharge switch set (14) is formed to open when the automatic activation function of the driving element (10) is activated. By being, cooling circuit of a motor lock, characterized in that it is possible to speed up the discharge of the activation discharge capacitor (13). In addition, a resistor (15) is included, the resistor (15) is connected in series between the starting discharge capacitor (13) and the discharge switch set (14), and the resistance value of the resistor (15) is set to discharge the starting discharge capacitor (13). The motor lock temperature reduction circuit according to claim 1, wherein the temperature reduction circuit can be used to determine an acceleration rate. When the operation of the motor is abnormal, the automatic activation function of the driving element (10) is activated, and when the driving element (10) outputs a high level, the discharge switch set (14) is opened. The motor lock temperature reduction circuit according to claim 1, wherein the discharge of the starting discharge capacitor (13) can be accelerated by being formed. When the operation of the motor is abnormal, the automatic activation function of the driving element (10) is activated, and when the driving element (10) outputs a low level, the discharge switch set (14) is opened. The motor lock temperature reduction circuit according to claim 1, wherein the discharge of the starting discharge capacitor (13) can be accelerated by being formed. The motor lock temperature decreasing circuit according to claim 1, wherein the coil (11, 31) is formed of a two-phase coil. The motor lock temperature reduction circuit according to claim 1, wherein the coil (21) is a single-phase coil. The motor lock temperature reduction circuit according to claim 1, wherein the discharge switch set (23) comprises a pair of diodes (D1, D2). The temperature reduction circuit for a motor lock according to claim 1, wherein the discharge switch set (23) comprises a transistor (231) and a pair of capacitors (232).

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